Cash register



Oct. 9, 1945. p SPURLINQ ETAL 2,386,364

CASH REGISTER Filed July 16, 1941 15 Sheets-Sheet l FIG. 1

FIG. 3

ITEM CONTROL BA N K UNIT LOCK LEVER.

Pascal Spurlino zg Arthur R. Cnllcy rcncc N. Lehman 9 Frcdcrick Gant 8 ISnnem-w Ti -j; (Ittorneg 9, 1945- P. SPURLINO ETAL 2,336,364

CASH REGISTER Filed July 16, 1941 15 Sheets-Sheet 2 Pasca .puriino 827 Arthur R. Collcy Laurence N. Lrhmzm and Frederick Gamm;

Unuenfors.

Get. 9, 1945. p SPURUNQ ETAL 2,386,364

CASH REGISTER Filed July 16, 1941 15 Sheets-Sheet 3 Pascal Spurlino Arthur R. Collcy Laurence N. Lehman and Frcdcrick Gantncr Zhwentors Their (Ittorneg Oct. 9, 1945. spu o r 2,386,364

CASH REGISTER Filed July 16, 1941 15 Sheets-Sheet 4 Pascal Spurlino Arthur R. Culley Laurence N. Lehman and F rcdcrick Gantner Imventors T i Cittorneg 1945. P. SPURLINO ETAL 2,336,364

CASH REGISTER Filed July 16, 1941 15 Sheets-Sheet 5 Pascal Spurlino Arthur R. Coll Laurcncc N. L an cdc and Fr rick Gantncr Imnentors Their Cittorneg Oct. 9, 1945. P. SPURLINO ETAL 2,386,364

CASH REGI STER Filed July 16, 1941 15 Sheets-Sheet 6 FIG. 1 62 C Charg Pasca urlino Arthu C0 1:

rencc N. man Frederick Gantner ZSnnentors ByWW Their (Ittomeg Oct. 9, 194-5. p SPURLINO E 2,386,364

CASH REGISTER Filed July 16, 1941 15 Sheets-Sheet 7 Pascal Spurlinn Arthur R. Coll Lnurv N. I, an and F rick (ianlncr Snvenfors By 6 QM W Th6 Oitorneg 1945- P. SPURLINO ET AL 2,336,364

CASH REGISTER Filed July 16, 1941 15 Sheets-Sheet 8 Pascal Spurlinn Arthur R. Cnlhy Thai! duo-nun Oct. 9, 1945. p SPURLINO ETAL 2,386,364

CASH REGISTER Filed July 16, 1941 15 Sheets-Sheet 9' E :0: //4 FF? him i- J IIIIIIIIIIIIIIIII ll ll I lilll Pascal Spurlino Arthur R. Collcy Laurence N. Lehman and Frcdzrick Gantncr 3nnentors Their Gttorneg 1945- P. SPURLINO ETAL 2,386,364

CASH REGISTER Filed July 16, 1941 is Sheets-Sheet 1o Pascal Spurlino Arthur R. Colic Laurence Le 11 and Frcdc Gantner Zmnentors Thu'rattorneg Oct. 9, 1945. p spu o r 2,386,364

CASH REGISTER Filed July 16, 1941 15 Sheets-Sheet 11 250 (a) 2 250 F|G.27

Pascal Spurlino Arthur R. Colley Laurence N. Lehman and F redcrick Gantner Zinuentors WWW Oct. 9, 1945. SPURLINQ ETAL 2,386,364

CASH REGISTER Filed July 16, 1941 15 Sheets-Sheet l2 Pascal Spurlino Arthur R. Collcy Laure N. Lehman and F r .rick Gantner ISnnentors Thu: attorney Oct. 9, 1945. p SPURLINO L 2,386,364

CASH REGISTER Filed July 16, 1941 15 Sheets-Sheet 13 FIG. 34

Pascal Spurlino Arthur R. Collcy Laurence N. Lehman and Frederick Gantner Z'mventora Zi 1am Their attorney 9, 1945- P.-SPURL|NO ETAL 2,386,364

CASH REGI S TER Filed July 16, 1941 15 Sheets-Sheet 14 Pascal Spurlino Arthur R. Collcy Laurence N. Lehman and F rcdcrick Gantncr 3nnenfors Their (Ittorneg P. SPURLINO ETAL 2,386,364

CASH REGISTER Filed July 16, 1941 l5 Sheets-Sheet l5 Pascal Spurlino Arthur R. Collcy Lnurcncc N Lehman and Frcdcrick Gamm-r ISnventors Patented Oct. 9, 1945 CASH REGISTER Pascal Spuriino, Arthur R. Colley,

Lehman, and Frederick Gantner, assignors to The National Cash Laurence N. Dayton, Ohio, Register Company, Dayton, Ohio, a corporation of Maryland Application July 16, 1941, Serial No. 402,590

30 Claims.

This invention relates to cash registers and accounting machines and is more particularly directed to the totalizer engaging and controlling mechanisms thereof.

The machine shown in the accompanying drawings is of the general type shown and described in United States Letters Patent Nos. 1,619,796 and 1,749,960, issued March 1. 1927, and March 11. 1930, respectively, to Bernis M. Shipley; and No. 1.917.356, issued July 11, 1933, to Samuel Brand. The indicating mechanism employed in connection therewith is of the so-called pentagon" type, which is fully illustrated and described in the patent of Frank R. Werner, No. 2,279,805, issued April 14. 1942. Used in connection with the indicating mechanism and the totalizer selccting mechanism is external-internal gear drive mechanism of the type disclosed in United States Letters Patent No. 1,693,279, issued November 27. 1928, to Walter J. Kreider.

Heretofore, in machines of this type, provided with one or more lines of interspersed totalizers, a manually adjustable total control device was employed for conditioning the machine to perform a single cycle of operation for adding amounts upon the totalizers, or a double cycle of operation for taking a total or a sub-total from the totalizers. When it was desired to take an amount off of one totalizer and transfer the amount to another totalizer, it was also necessary to condition the machine for a double cycle of operation by manually adjusting the total control device to one of its various total taking positions.

The present invention enables the taking of a total from one totalizer and the automatic transfer thereof to another totalizer during a single cycle of operation, while the total control device remains in its normal add position. It will readily be seen that such an arrangement is particularly advantageous when it is desired to take a total of a multiple-item transaction, clear the multiple-item totalizer, and transfer the amount taken therefrom to a group totalizer, without the necessity of manually moving the total control device to a position to condition the machine for performing the regular two-cycle operation usually necessary for accomplishing such results.

It is, therefore, a primary object of the invention to provide a novel totalizer control mechanism which is characterized by its flexibility and selectivity.

Another object of the invention i to provide mechanism, controlled by a differentially adjustable control device, for conditioning the machine to perform single-cycle adding operations and double-cycle total taking operations, and means adapted under certain conditions, when the device is adjusted for single-cycle adding operations, to supersede the control exercised by said device over the mechanism to enable the machine to be operated to take an amount off of one totalizer, reset said totalizer to zero, and transfer such amount to another totalizer in the same row during a single cycle of operation.

Another object of the invention is to provide a novel arrangement for selecting and engaging the totalizers during item entering operations and item total taking operations.

Another object of the invention is to provide novel means for transferring totals taken from one totalizer to another totalizer of the same row.

Another object of the invention is to provide a novel arrangement for machine release, in accordance with the various kinds of transactions performed.

Another object of the invention is to provide novel interlocking means for certain keys, and means to control the operation of the interlocking means in various kinds of machine operations.

Another object of the invention is the provision of novel means for taking a total from an item totalizer and automatically transferring it to a group totalizer, both carried on the same line, during a single cycle of operation.

A further object of the invention is the provision of means for selectively engaging one or all of a plurality of totalizer lines simultaneously with a common actuating mechanism during an adding operation.

With these and incidental objects in view, the invention includes certain novel features of construction and combinations of parts, the essential elements of which are set forth in appended claims and a preferred form or embodiment of which is hereinafter described with reference to the drawings which accompany and form a part of this specification.

Of said drawings:

Fig. 1 is a diagrammatic representation of the keyboard of the illustrated machine.

Fig. 2 is a detail side view of a totalizer selecting disk, which is differentially adjustalble under control of the unit lock lever, and the pawls or feelers coacting therewith.

Fig. 3 is a detail side view. of another totalizer selecting disk, which is differentially adjustable under control of the bank of item control keys, and the pawls or feelers coacting therewith.

Fig. 4 is a detail side view of another totalizer selecting disk, which is differentially adjustable under control of the transaction bank of keys, together with its associated pawls and feelers.

Fig. 5 is a vertical section through a portion of the machine, showing the total key and associated mechanism for controlling the engagement of the totalizers during either single-cycle or double-cycle sub-total and total taking operations.

Fig. 6 is a detail side view of the means actuated by the key lock line for connecting the throwout reset line to the cam actuating mechanism and retaining the total key depressed during total taking operations.

Fig. '7 is a detail vertical section through a portion of the machine, showing the means for shifting the upper totalizer line.

Fig. 8 is a detail side view of the lower portion of the mechanism shown in Fig. 6.

Fig. 9 is a vertical section through a portion of the machine, showing the unit lock lever and the means actuated thereby for adjusting its corresponding totalizer selecting disk, together with the mechanism for conditioning the machine for one-cycle operations and two-cycle operations.

Fig. 10 is a side elevation of the bank of item control keys, showing the mechanism controlled thereby for differentially adjusting the totalizer selecting disk associated therewith.

Fig. 11 is a detail fragmentary view of the unit lock lever, showing its various positions of adjustment.

Fig. 12 is a side elevation of the clerks bank of keys and the mechanism controlled thereby for shifting laterally the lower totalizer line to effect a variable selection of clerks totalizers for engagement with they actuators.

Fig. 13 is a detail right-hand side view of devices controlled by the banks of multiple-item and single-item keys for releasing the machine for operation, and interlocks associated therewith.

Fig. 14 is a detail view of the clerk's bank looking detent and its controlling means from the multiple-item and single-item bank.

Fig. 15 is a right side elevation of the bank of transaction keys and the mechanism controlled thereby for differentially adjusting the totalizer selecting disk associated therewith.

Fig. 16 is a detail fragmentary side View of the upper portion of the bank of transaction keys.

Fig. 1''! is a left side elevation of the bank of transaction keys shown in Figs. 15 and 16, showing additional detents associated therewith.

Fig. 18 is a side-elevation of a bank of amount keys and the differential mechanism controlled thereby.

Fig. 19 is a detail side view of the means by which the totalizer wheels control the adjustment of the amount difierential actuator during totalizer reading or resetting operations.

Fig. 20 is a detail side view of the latch operating mechanism associated with an amount differential actuator.

Fig. 21 is a front elevation of the upper totalizer line, showing a portion of the means for shifting the same relatively to the actuators.

Fig. 22 is a, front elevation of the lower totalizer line, showing the means for shifting the same laterally relatively to the actuators.

Fig. 23 is a detail side view of the portion of the means controlled by the clerks bank of keys for shifting the lower totalizer line.

Fig. 24 is a side view of the totalizer engaging means.

Fig. 25 is a detail side view of a portion of the totalizer selecting means.

Fig. 2691s a side view of the mechanism. for controlling the engagement or non-engagement of the upper totalizer line with the actuators, showing the parts in theirohome positions.

Fig. 27 is a view of he mechanism shown in Fig. 26, showing the parts in the positions to which they are moved during the first half-cycle of an adding operation to prevent the upper totalizer line from being moved into engagement with the actuators.

Fig. 28 is a view of the same mechanism shown in Figs. 26 and 27, showing the feeling member coacting with unnotched portions of the peripheries of the selecting disks at the end of the first half-cycle of operation, thereby preventing the upper totalizer line from being moved into engagement with the actuators during the last half of said cycle of operation.

Fig. 28 is like Fig. 28 except that it shows the feeling member coacting with notched portions of the peripheries of the selecting disks, thereby causing the upper totalizer to be moved into engagement with the actuators during the last half of the cycle of operation.

Fig. 30 is a view of the mechanism illustrated in Figs. 26, 27, 28, and 29, showing the positions assumed by the parts shortly after the beginning of the first half of the cycle of operation, when the upper totalizer line is moved. into engagement with the actuators in order that the latter may take off the amount on said totalizer and add it on another totalizer on said line during the last half-cycle of said operation.

Fig. 31 is a side view of a portion of the totalizer selecting plate associated with the bank of transaction keys, together with the totalizer engaging mechanism controlled thereby.

Fig. 31A is a detail view showing the dotted cam race of Fig. 31 in full lines.

Fig. 32 is a front elevation of a portion of the mechanism shown in Fig. 31.

Fig. 33 is a fragmentary front view of a portion of the mechanism shown in Fig. 31.

Fig. 34 is a front elevation of the train of external-internal gear drive mechanism.

Fig. 35 is a top plan view of the machine release line.

Fig. 36 is a top plan view of the upper reset line.

Fig. 37 is a vertical section through a portion of the machine, showing the indicating mechanism and the means for differentially setting the same.

Fig. 38 is a detail top plan view of one of the indicators employed in the present machine.

Fig. 39 is a fragmentary view of the upper portion of the machine, showing certain of the indicators.

Fig. 40 is a side view of a portion of the mechanism for raising and lowering the indicators.

Figs. 41, 42, 43, and 44 are detail right-hand side views of the devices controlled by the banks of amount keys for releasing the machine for operation, as well as certain interlocks associated therewith.

Figs. 45, 46, and 49 are detail right-hand side views of the devices controlled by the transaction bank of keys for releasing the machine for opi read eration, as well as certain interlocks related thereto.

Figs. 47, 48, and 50 are detail right-hand side views of the devices controlled by the clerks bank of keys for releasing the machine, and the interlocks associated therewith.

Figs. 51 and 52 are detail right-hand side views of the devices controlled by the bank of multiple-item and single-item keys for releasing the machine for operation, and the interlocks related to the same.

General description The machine embodying this invention is arranged to record single-item transactions and multiple-item transactions, A single-item transaction consists of the entering of a single item in the group totalizer and in the selected clerks totalizer, and the setting up of this item on the indicators.

A multiple-item transaction consists of a series of item-entering operations followed by a clearing operation. During the item entering operations, the items are accumulated in the multipleitem totalizer and in the proper clerk's totalizer, and are set up on the indicators as the items are entered in the totalizers. In the clearing operation following a series of multiple-item entering operations, the multiple-item totalizer is reset to zero, and the total is automatically transferred to the group totalizer and set up on the indicators, all during a single-cycle machine operation.

In recording a multiple-item transaction wherein there is a tax involved, instead of clearing the multiple-item totalizer following the entry of the last item of such a transaction, a operation is performed, which causes a sub-total to be set up on the indicators, without clearing the totalizer, during a single-cycle machine operation. Theoperator then computes the amount of tax based on the sub-total amount displayed on the indicators, and causes such tax to be added into the multiple-item totalizer. The multiple-item totalizer is afterward reset to zero, and the total of all the items comprised in such multiple-item transaction, including the tax, is automatically transferred to the group totalizer and set up on the indicators, during a single-cycle machine operation.

In machines performing these operations, it is highly desirable that various keys should be operated in certain operations and be blocked against operation in others. It is also necessary that keys be released in certain operations and be retained depressed in other operations. Novel mechanisms have been provided herein for insuring that the keys will be locked and released under the proper conditions.

When it is desired to read or reset to zero the group totalizer or any one of the clerks totalizers, it is necessary to adjust the unit lock lever (total control device) to the proper one of its various positions of adjustment to condition the machine for a double-cycle operation.

The type of machine disclosed in the present application includes, generally, a plurality of interspersed totalizers, control keys, and difierential mechanisms associated therewith for selecting the desired totalizer; a plurality of banks of amount keys and differential mechanisms associated therewith for adding amounts set up thereon into the selected totalizers; and total and sub-total control mechanism.

Printing mechanism may be provided for the purpose of printing on one or a plurality of record materials the various amounts registered. and the totals and sub-totals accumulated on the various totalizers. The present machine is shown equipped with indicators for displaying the above data to the public upon operation of the machine.

Machines of this type usually employ a plurality of rows of interspersed totalizers for classifying and recording the various data set up on the keyboard of the machine. Also provided in such machines are means, under control of the differentially adjustable control device (unit lock lever), which condition the machine either for a single cycle of operation to perform a regular adding operation, or for a double cycle of operation to perform a total or sub-total taking 0p- I eration, otherwise known in this art as a reset" operation or a read operation, respectively.

In order to take an amount off of one totalizer and transfer such amount to another totalizer in such types of machines, it is necessary to adjust the total control device to condition the machine for a two-cycle operation.

While the machine herein illustrated is pro vided with all of the above mentione mechanisms for accomplishing the results set forth, it also includes novel means for greatly increasing the flexibility and selectivity of the totalizer semechanism. For example, with the present invention, it is possible, after registering all the items of a multiple-item transaction, to take the total off of the multiple-item totalizer, reset said totalizer to zero, and transfer such total amount to a group totalizer in the same row, during a single cycle of operation, without moving the control device out of its normal acid position.

Interlocks are provided between the various kinds of keys and the unit lock lever to retain the operated transaction and clerks keys depressed during multiple-item operations, as well as to prevent operation of the keys and the unit lock lever during other kinds of operations, as will be described more in detail hereinafter.

Keyboard The keyboard of the present machine is diagrammatically shown in Fig. 1 and includes a plurality of banks of amount keys 6| three rows of control keys comprising a bank of transaction keys 62, a bank of clerks keys 63, and a bank of multiple-item and single-item keys 64 and 65, respectively; a differentially adjustable unit lock total control lever 66; and a total key 61.

Amounts to be entered on one or another of the plurality of totalizers in the machine are set up by depressing the appropriate amount keys 5| (Figs. 1 and 18), arranged in denominational banks. Each of these banks of keys 6| is provided with a differential mechanism to add into the denominational wheels of the selected totalizer the amount set up on the amount keys and to control the adjustment of the indicators accordingly.

The transaction keys 62 (Figs. 15, 16, and 17) control the selection of totalizers into which the amounts set up on the amount keys 6| are to be added, as well as control the adjustment of the indicators and certain other elements in the machine for taking a sub-total from the itemizing totalizer and a total from the group totalizer,

The clerks keys 63 (Fig. 12) control the selection of the clerks totalizers into which amounts set up on the amount keys are to be added, as

well as control the adjustment of the indicators associated therewith.

The bank of multiple-item and single-item keys 64 and 85 (Fig. 10), respectively, controls mechanism for selecting either the multiple-item totalizer or the group totalizer, into which the amounts set up on the amount keys are to be added.

The unit lock lever 88 (Figs. 9 and 11) controls the adjustment of certain elements for conditioning the machine to perform single-cycle adding operations and double-cycle total or sub-total taking operations.

The total key 81 (Fig. 5) is adapted, when the unit lock lever 88 is adjusted for single-cycle adding operations, to supersede the control of said lever over certain elements in the machine to cause the latter to take a total from the item totalizer and transfer such total to the group totalizer during a single cycle of operation.

Amount keys As previously stated, the machine herein illustrated has four banks of amount keys 8i, and, inasmuch as all of the amount banks and their associated differential mechanisms are identically alike, it is thought that a description of one denominational unit will suffice for all.

Referring to Fig. 18, it will be seen that the amount keys 8| are slidably mounted in a frame I8 which is removably supported on rods Ti and I8 extending between and supported by the main side frames I9 and 80 (Figs, 21 and 22) of the machine.

The amount keys 8| are normally maintained in their undepressed positions by the usual coil springs 8| (only one of which is shown). When a key BI is depressed, it is held in depressed position by a locking detent 82 supported at its upper end by a bell crank 14 and at its lower end by an arm (not shown), both said bell crank and said through the lever IOI, returns the zero stop 98 and the bar 91 to their normal positions. Amount differential mechanism There are provided in the machine as many amount differential mechanisms as there are amount banks of keys, and there may be one or more additional differential mechanisms to take care of the overflow amounts. Inasmuch as each of said differential mechanisms is identically the same, a description of one will sumce for all. Each differential mechanism is controlled by its respective bank of amount keys M to accumulate on totalizers and adjust indicators and type wheels during adding operations.

The present machine is adapted to perform single-cycle operations and double-cycle operations, a single cycle of operation involving 'one complete revolution of amain drive shaft I06, while a double-cycle operation requires two complete revolutions of the main drive shaft. The

- means for conditioning the machine to perform arm being pivotally mounted on the frame 18.

Depression of an amount key 8i causes a pin 83 carried thereby to coact with a cam portion of a hook 84 on the detent 82 to cam the latter downwardly against the action of the usual spring (not shown) until the pin 88 clears the hook 8 3, whereupon said spring moves the detent 82 upwardly to lock the hook 84 over the pin 83 to retain said key in its depressed position. Near the end of the operation, the detent 82 is again moved downwardly, by mechanism to be hereinafter described, to disengage the hook 84 from the pin 83, thus releasing the key BI to the action of the coil spring 0|, which moves the key outwardly to its normal undepressed position.

A zero stop 95 (Fig. 18) is provided for causing the differentially movable actuator to be arrested in zero position when the machine is operated with no key depressed. During adding operations, this stop is moved out of its normal effective position by depression of any one of the keys 8|. When an amount key is depressed, the pin 83 thereon coacts with the cam portion 98 of a control bar 91 to cam the latter downwardly against the action of e sp..ng 98. Said bar is pivoted at ts upper end to an arm 93 (Fig. 451) loose on a stud 94 mounted in the frame 18, and at its lower end by a curved arm 99 pivotally mounted on the frame I8. When the bar 91 is moved downwardly, it rocks the arm 99 clockwise, which, through a pin I00 on one end of a lever IOI pivoted at I02 to the frame 18, rocks the lever IOI counter-clockwise against the action of a spring 98. The other end of the lever IOI such operations will be hereinafter described.

Each differential mechanism includes a differentially movable actuator lII (Fig. 18) provided with racks H2 and transfer carrying arms NS for operating totalizer wheels H4 and ill arranged on one line, and H5 arrange on another line. The transfer mechanism (Fig. 19) which controls the arms H8 is hereinafter described. While the actuator Ili is shown provided with three racks I I2 for operating totalizer wheels on a like number of different lines, only two such lines ar used in the present machine, and consequently only two of said racks will be efiective.

The actuator Ill is loosely mounted on a shaft M0 carried by the machine side frames I9 and 80. During each cycle of operation of the machine, the actuator II! is driven first in a clockwise direction and then in a counter-clockwise direction by a segmentally shaped driver I2I also loosely mounted on the shaft H8, which driver is given an invariable excursion of movement, during each cycle of operation of the machine, by means to be hereinafter described.

The actuator III is connected to the driver I2I by means of a latch I22 pivotally mounted on an arm I23 also loose on the shaft H8. A pin I24 on the latch I22 projects through a slot I25 in the actuator III. Arranged parallel with and adjacent to the actuator I I l is a counter-balance v plate I28, said plate being loose on the shaft H8 and resiliently connected to the actuator I II by a spring I21. The plate I26 is provided with a. curved slot I28 substantially at right angles to the inclined slot I25 in the actuator III. The pin I24 also projects [through and works in the slot I28. Thus the plate I26, through the slot I28 and its resilient connection with the actuator III, normally serves to hold the pin I24 at the bottom of the slot I25 in the actuator III, to thereby maintain the latch I22 in engagement with a shoulder I29 formed on the driver I2I. With the latch I22 thus engaged with key and thereby the shoulder I29, the driver I2 I, during its clockwise movement, moves the actuator III and the plate I26 clockwise until the latch I22 is disenazed from the driver, under control of either the zero stop 05 or a depressed amount key 6|, in the case of an adding operation. If it is a total taking operation, then the actuator III is arrested under control of the selected one of the totalizer wheels H4, H5, or II1, as will be described later.

When one of the keys H is depressed, the lower end thereof is positioned in the path of movement of a projection I30 on the actuator III. Thus, when the actuator I II and its associated plate I26 are moved clockwise by the driver I2I, the projection I30 strikes the end of the depressed III. When this occurs, the latch I22 and the plate I26 continue to move clockwise relatively to the actuator until the slot I25, coacting with the pin I24, cams the latch I22 counter-clockwise, against the action of the slot I28 in the .plate I26, to disengage the latch from the driver I2 I. When the latch I22 is thus disengaged from the driver I2I, a projection I3I formed on said latch engages one of a series of notches I32 in a stationary locking plate I33 to maintain said latch and the actuator in their differentially set positions.

Through the camming action of the slot I25 on 'the pin I24, under the influence of the yieldable means formed by the spring I21, the plate I26, and the actuator I I I, the possibility of premature disengagement of the latch I22 from the driver I2I, when the machine is operated at excessive speed, is obviated. In addition, such an arrangement facilitates disengagement of the latch from the driver at the proper time and thereby reduces to a minimum the amount of load thus placed on the main drive shaft of the machine.

The means for giving the driver I2I associated with the amount differential bank shown in Fig. 18, and all the rest of the drivers associated with the rest of the amount banks and any overflow banks, their invariable excursions of movement during each cycle of operationof the machine, includes an oscillating frame consisting of a lever I40 (Fig. 15) and a lever I (Fig. 18) connected by a rod I42. The lever I40 is pivoted on a stud I43 carried by a supporting plate or hanger I44 (Fig. 15), which in turn is supported on rods I45 and I46 carried by the machine side frames 19 and 80. The lever I4I is pivoted on a stud I41 secured to a hanger I48 like the hanger I44. The hanger I48 is supported by the rods I45 and I46. There is a. hanger I48 associated with each of the amount differential units.

The lever I 40, which is near the right-hand side of the machine, carries rollers I49 and I 50 cooperating with plate cams I5I and I52, respectively, which ar secured together and fastened on the main drive shaft I06.

Secured to the lever I 4| are rollers I53 and I54 cooperating with plate cams I55 and I56, which are secured together and also fastened to the main cam shaft I06. These cams I55 and I56 and the lever I are located adjacent the lefthand side of the machine.

The rod I 42 fits loosely in the levers I 40 and I to permit the ends of the rod I42 to be moved in slightly difierent timing. The right end of the rod I42 starts to move downwardly (Fig. 15) at about degrees ahead of the left end thereof. To obtain this result, the section of the cams I5Il52 and I 55I56, which are effective to arrests movement of the actuator I position 10 lower the respective ends of rod I42, are alike except that they are displaced on the shaft I06 a distance equal to 10 degrees of movement of the shaft I06. Therefore, during the initial, or downward, movement of the shaft I42, the right-hand end thereof starts to move 10 degrees ahead of the left-hand end, and it also reaches its lowermost degrees ahead of the left-hand end thereof. After both ends of the shaft I 42 have reached their lowermost positions, shaft I 42 is again in a horizontal position, they are so held by dwells in said cams.

During the return movement upwardly of the rod I42, both ends thereof start at the same time, but the effective sections of the cams I5I-l52 and I55'I56 are so developed that the lever I moves faster than the lever I. To obtain this result, the effective sections of cams I5II 52 and I 55.I56 are such that the former completes the upward movement of lever I 40 10 degrees ahead of the movement of lever MI by cams I 55I 56. At the end of the return movement of rod I42, it is again in horizontal position, as shown.

The purpose of the loose fit of the rod I42 in the levers I40 and MI is to allow for this nonparaliel movement of the levers I40 and HI. In other words, the right-hand end of the rod I42, which is the end near the cams I SI and I 52, is of that end of the rod which is near the cams I55 and I56. About the middle of the operation, the rod I42 again becomes parallel with the shaft I06, and finally, on the return movement upwardly to normal position, that end of the rod I42 adjacent the cams I5I and I52 starts upwardly simultaneously with the other end of the rod and returns home Connected to each driver I2I (Fig. 18) is a link I51 pivoted to the upper end of a lever I58, which is pivoted on a stud I41. The lower ends of these levers surround the rod I42.

From the above description, it will be clear that the rocking clockwise of the frame consisting of levers I40 and HI and the rod I42, through the connections of levers I58 to the rod I42, draws the links I51 to the right, thus rocking the drivers clockwise in the manner previously mentioned to drive the differentials through the latch mechanism.

As the cams I5I, I52, I55, and I56 return to normal positions, the frame consisting of levers I40 and MI and rod I42 is rocked counter-clockwise, thus restoring the drivers I 2I to their normal positions.

There is a lever I58 connected to each of the drivers I2I, and, as thes levers are connected at various distances along the rod motion of one end of the rod ahead of the other end of the rod as it is moved downwardly causes the drivers I2I to be successively operated-that normal positions in succession.

Moreover, as these drivers restore the differen- 

